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4.5E: Exercises for Section 4.5

  • Page ID
    102735
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    1) If \(c\) is a critical point of \(f(x)\), when is there no local maximum or minimum at \(c\)? Explain.

    2) For the function \(y=x^3\), is \(x=0\) both an inflection point and a local maximum/minimum?

    Answer
    It is not a local maximum/minimum because \(f'\) does not change sign

    3) For the function \(y=x^3\), is \(x=0\) an inflection point?

    4) Is it possible for a point \(c\) to be both an inflection point and a local extremum of a twice differentiable function?

    Answer
    No

    5) Why do you need continuity for the first derivative test? Come up with an example.

    6) Explain whether a concave-down function has to cross \(y=0\) for some value of \(x\).

    Answer
    False; for example, \(y=\sqrt{x}\).

    7) Explain whether a polynomial of degree \(2\) can have an inflection point.

    In exercises 8 - 12, analyze the graphs of \(f'\), then list all intervals where \(f\) is increasing or decreasing.

    8)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at (−2, 0). Then it continues increasing a little before decreasing and crossing the x axis at (−1, 0). It achieves a local minimum at (1, −6) before increasing and crossing the x axis at (2, 0).

    Answer
    Increasing for \(−2<x<−1\) and \(x>2\);
    Decreasing for \(x<−2\) and \(−1<x<2\)

    9)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at (−2, 0). Then it continues increasing a little before decreasing and touching the x axis at (−1, 0). It then increases a little before decreasing and crossing the x axis at the origin. The function then decreases to a local minimum before increasing, crossing the x-axis at (1, 0), and continuing to increase.

    10)

    The function f’(x) is graphed. The function starts negative and touches the x axis at the origin. Then it decreases a little before increasing to cross the x axis at (1, 0) and continuing to increase.

    Answer
    Decreasing for \(x<1\),
    Increasing for \(x>1\)

    11)

    The function f’(x) is graphed. The function starts positive and decreases to touch the x axis at (−1, 0). Then it increases to (0, 4.5) before decreasing to touch the x axis at (1, 0). Then the function increases.

    12)

    The function f’(x) is graphed. The function starts at (−2, 0), decreases to (−1.5, −1.5), increases to (−1, 0), and continues increasing before decreasing to the origin. Then the other side is symmetric: that is, the function increases and then decreases to pass through (1, 0). It continues decreasing to (1.5, −1.5), and then increase to (2, 0).

    Answer
    Decreasing for \(−2<x<−1\) and \(1<x<2\);
    Increasing for \(−1<x<1\) and \(x<−2\) and \(x>2\)

    In exercises 13 - 17, analyze the graphs of \(f'\), then list all intervals where

    a. \(f\) is increasing and decreasing and

    b. the minima and maxima are located.

    13)

    The function f’(x) is graphed. The function starts at (−2, 0), decreases for a little and then increases to (−1, 0), continues increasing before decreasing to the origin, at which point it increases.

    14)

    The function f’(x) is graphed. The function starts at (−2, 0), increases and then decreases to (−1, 0), decreases and then increases to an inflection point at the origin. Then the function increases and decreases to cross (1, 0). It continues decreasing and then increases to (2, 0).

    Answer
    a. Increasing over \(−2<x<−1,\;0<x<1,x>2\), Decreasing over \(x<−2, \;−1<x<0, \;1<x<2;\)
    b. Maxima at \(x=−1\) and \(x=1\), Minima at \(x=−2\) and \(x=0\) and \(x=2\)

    15)

    The function f’(x) is graphed from x = −2 to x = 2. It starts near zero at x = −2, but then increases rapidly and remains positive for the entire length of the graph.

    16)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at the origin, which is an inflection point. Then it continues increasing.

    Answer
    a. Increasing over \(x>0\), Decreasing over \(x<0;\)
    b. Minimum at \(x=0\)

    17)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at (−1, 0). Then it continues increasing a little before decreasing and touching the x axis at the origin. It increases again and then decreases to (1, 0). Then it increases.

    In exercises 18 - 22, analyze the graphs of \(f'\), then list all inflection points and intervals \(f\) that are concave up and concave down.

    18)

    The function f’(x) is graphed. The function is linear and starts negative. It crosses the x axis at the origin.

    Answer
    Concave up for all \(x\),
    No inflection points

    19)

    The function f’(x) is graphed. It is an upward-facing parabola with 0 as its local minimum.

    20)

    The function f’(x) is graphed. The function resembles the graph of x3: that is, it starts negative and crosses the x axis at the origin. Then it continues increasing.

    Answer
    Concave up for all \(x\),
    No inflection points

    21)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at (−0.5, 0). Then it continues increasing to (0, 1.5) before decreasing and touching the x axis at (1, 0). It then increases.

    22)

    The function f’(x) is graphed. The function starts negative and crosses the x axis at (−1, 0). Then it continues increasing to a local maximum at (0, 1), at which point it decreases and touches the x axis at (1, 0). It then increases.

    Answer
    Concave up for \(x<0\) and \(x>1\),
    Concave down for \(0<x<1\),
    Inflection points at \(x=0\) and \(x=1\)

    For exercises 23 - 27, draw a graph that satisfies the given specifications for the domain \(x=[−3,3]\). The function does not have to be continuous or differentiable.

    23) \(f(x)>0,\;f'(x)>0\) over \(x>1,\;−3<x<0,\;f'(x)=0\) over \(0<x<1\)

    24) \(f'(x)>0\) over \(x>2,\;−3<x<−1,\;f'(x)<0\) over \(−1<x<2,\;f''(x)<0\) for all \(x\)

    Answer
    Answers will vary

    25) \(f''(x)<0\) over \(−1<x<1,\;f''(x)>0,\;−3<x<−1,\;1<x<3,\) local maximum at \(x=0,\) local minima at \(x=±2\)

    26) There is a local maximum at \(x=2,\) local minimum at \(x=1,\) and the graph is neither concave up nor concave down.

    Answer
    Answers will vary

    27) There are local maxima at \(x=±1,\) the function is concave up for all \(x\), and the function remains positive for all \(x.\)

    For the following exercises, determine

    a. intervals where \(f\) is increasing or decreasing and

    b. local minima and maxima of \(f\).

    28) \(f(x)=\sin x+\sin^3x\) over \(−π<x<π\)

    Answer

    a. Increasing over \(−\frac{π}{2}<x<\frac{π}{2},\) decreasing over \(x<−\frac{π}{2},\; x>\frac{π}{2}\)

    b. Local maximum at \(x=\frac{π}{2}\); local minimum at \(x=−\frac{π}{2}\)

    29) \(f(x)=x^2+\cos x\)

    For exercise 30, determine

    a. intervals where \(f\) is concave up or concave down, and

    b. the inflection points of \(f\).

    30) \(f(x)=x^3−4x^2+x+2\)

    Answer

    a. Concave up for \(x>\frac{4}{3},\) concave down for \(x<\frac{4}{3}\)

    b. Inflection point at \(x=\frac{4}{3}\)

    For exercises 31 - 37, determine

    a. intervals where \(f\) is increasing or decreasing,

    b. local minima and maxima of \(f\),

    c. intervals where \(f\) is concave up and concave down, and

    d. the inflection points of \(f\).

    31) \(f(x)=x^2−6x\)

    32) \(f(x)=x^3−6x^2\)

    Answer
    a. Increasing over \(x<0\) and \(x>4,\) decreasing over \(0<x<4\)
    b. Maximum at \(x=0\), minimum at \(x=4\)
    c. Concave up for \(x>2\), concave down for \(x<2\)
    d. Inflection point at \(x=2\)

    33) \(f(x)=x^4−6x^3\)

    34) \(f(x)=x^{11}−6x^{10}\)

    Answer
    a. Increasing over \(x<0\) and \(x>\frac{60}{11}\), decreasing over \(0<x<\frac{60}{11}\)
    b. Maximum at \(x=0\), minimum at \(x=\frac{60}{11}\)
    c. Concave down for \(x<\frac{54}{11}\), concave up for \(x>\frac{54}{11}\)
    d. Inflection point at \(x=\frac{54}{11}\)

    35) \(f(x)=x+x^2−x^3\)

    36) \(f(x)=x^2+x+1\)

    Answer
    a. Increasing over \(x>−\frac{1}{2}\), decreasing over \(x<−\frac{1}{2}\)
    b. Minimum at \(x=−\frac{1}{2}\)
    c. Concave up for all \(x\)
    d. No inflection points

    37) \(f(x)=x^3+x^4\)

    For exercises 38 - 47, determine

    a. intervals where \(f\) is increasing or decreasing,

    b. local minima and maxima of \(f\),

    c. intervals where \(f\) is concave up and concave down, and

    d. the inflection points of \(f\). Sketch the curve, then use a calculator to compare your answer. If you cannot determine the exact answer analytically, use a calculator.

    38) [T] \(f(x)=\sin(πx)−\cos(πx)\) over \(x=[−1,1]\)

    Answer
    a. Increases over \(−\frac{1}{4}<x<\frac{3}{4},\) decreases over \(x>\frac{3}{4}\) and \(x<−\frac{1}{4}\)
    b. Minimum at \(x=−\frac{1}{4}\), maximum at \(x=\frac{3}{4}\)
    c. Concave up for \(−\frac{3}{4}<x<\frac{1}{4}\), concave down for \(x<−\frac{3}{4}\) and \(x>\frac{1}{4}\)
    d. Inflection points at \(x=−\frac{3}{4},\;x=\frac{1}{4}\)

    39) [T] \(f(x)=x+\sin(2x)\) over \(x=[−\frac{π}{2},\frac{π}{2}]\)

    40) [T] \(f(x)=\sin x+\tan x\) over \((−\frac{π}{2},\frac{π}{2})\)

    Answer
    a. Increasing for all \(x\)
    b. No local minimum or maximum
    c. Concave up for \(x>0\), concave down for \(x<0\)
    d. Inflection point at \(x=0\)

    41) [T] \(f(x)=(x−2)^2(x−4)^2\)

    42) [T] \(f(x)=\dfrac{1}{1−x},\quad x≠1\)

    Answer
    a. Increasing for all \(x\) where defined
    b. No local minima or maxima
    c. Concave up for \(x<1\); concave down for \(x>1\)
    d. No inflection points in domain

    43) [T] \(f(x)=\dfrac{\sin x}{x}\) over \(x=[-2π,0)∪(0,2π]\)

    44) \(f(x)=\sin(x)e^x\) over \(x=[−π,π]\)

    Answer
    a. Increasing over \(−\frac{π}{4}<x<\frac{3π}{4}\), decreasing over \(x>\frac{3π}{4},\;x<−\frac{π}{4}\)
    b. Minimum at \(x=−\frac{π}{4}\), maximum at \(x=\frac{3π}{4}\)
    c. Concave up for \(−\frac{π}{2}<x<\frac{π}{2}\), concave down for \(x<−\frac{π}{2},\;x>\frac{π}{2}\)
    d. Inflection points at \(x=±\frac{π}{2}\)

    45) \(f(x)=\ln x\sqrt{x},\quad x>0\)

    46) \(f(x)=\frac{1}{4}\sqrt{x}+\frac{1}{x},\quad x>0\)

    Answer
    a. Increasing over \(x>4,\) decreasing over \(0<x<4\)
    b. Minimum at \(x=4\)
    c. Concave up for \(0<x<8\sqrt[3]{2}\), concave down for \(x>8\sqrt[3]{2}\)
    d. Inflection point at \(x=8\sqrt[3]{2}\)

    47) \(f(x)=\dfrac{e^x}{x},\quad x≠0\)

    In exercises 48 - 52, interpret the sentences in terms of \(f\), \(f'\), and \(f''\).

    48) The population is growing more slowly. Here \(f\) is the population.

    Answer
    \(f>0,\;f'>0,\;f''<0\)

    49) A bike accelerates faster, but a car goes faster. Here \(f=\) Bike’s position minus Car’s position.

    50) The airplane lands smoothly. Here \(f\) is the plane’s altitude.

    Answer
    \(f>0,\;f'<0,\;f''>0\)

    51) Stock prices are at their peak. Here \(f\)is the stock price.

    52) The economy is picking up speed. Here \(f\) is a measure of the economy, such as GDP.

    Answer
    \(f>0,\;f'>0,\;f''>0\)

    For exercises 53 - 57, consider a third-degree polynomial \(f(x)\), which has the properties \(f'(1)=0\) and \(f'(3)=0\).

    Determine whether the following statements are true or false. Justify your answer.

    53) \(f(x)=0\) for some \(1≤x≤3\).

    54) \(f''(x)=0\) for some \(1≤x≤3\).

    Answer
    True, by the Mean Value Theorem

    55) There is no absolute maximum at \(x=3\).

    56) If \(f(x)\) has three roots, then it has \(1\) inflection point.

    Answer
    True, examine derivative

    57) If \(f(x)\) has one inflection point, then it has three real roots.


    This page titled 4.5E: Exercises for Section 4.5 is shared under a not declared license and was authored, remixed, and/or curated by Zoya Kravets.

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